The number of publications in the field of chemical cross-linking
combined with mass spectrometry (XL-MS) to derive constraints for protein
three-dimensional structure modeling and to probe protein–protein
interactions has increased during the last years. As the technique is now
becoming routine for in vitro and in vivo applications in proteomics and
structural biology there is a pressing need to define protocols as well as data
analysis and reporting formats. Such consensus formats should become accepted in
the field and be shown to lead to reproducible results. This first,
community-based harmonization study on XL-MS is based on the results of 32
groups participating worldwide. The aim of this paper is to summarize the status
quo of XL-MS and to compare and evaluate existing cross-linking strategies. Our
study therefore builds the framework for establishing best practice guidelines
to conduct cross-linking experiments, perform data analysis, and define
reporting formats with the ultimate goal of assisting scientists to generate
accurate and reproducible XL-MS results.
A major challenge in cross-linking/mass spectrometry (MS) is targeting carboxyl functions in proteins under physiological conditions that do not disturb the protein's conformation. Cross-linking of glutamic acid and aspartic acid residues in proteins will greatly expand the scope of structural mass spectrometry. We discovered that carboxyl-reactive cross-linkers have already been employed for many years in cross-linking/MS studies, yet in a completely different context. Diazirine-based cross-linkers, such as photomethionine and succinimidyldiazirine cross-linkers, are currently considered to react nonspecifically upon UV-A photoactivation with all 20 proteinogenic amino acids through a reactive carbene that inserts mainly into C-H bonds. We discovered that the cross-linking capability of diazirines based on X-H (X = C, N, O) insertion is in fact only the tip of the iceberg. Diazirines isomerize to linear diazo compounds that can react with carboxylic acids to yield esters. On top of that, the resulting cross-linked products are MS-cleavable allowing an automated analysis of cross-links via customized software tools. Therefore, diazirines open an entirely new route for photo-cross-linking of carboxylic acids. Previous cross-linking studies using diazirines have to be revisited in the light of these findings.
Cleavable cross-linkers are gaining increasing importance for chemical cross-linking/mass spectrometry (MS) as they permit a reliable and automated data analysis in structural studies of proteins and protein assemblies. Here, we introduce 1,3-diallylurea (DAU) as the first CID-MS/MS-cleavable, photo-thiol-reactive cross-linker. DAU is a commercially available, inexpensive reagent that efficiently undergoes an anti-Markovnikov hydrothiolation with cysteine residues in the presence of a radical initiator upon UV-A irradiation. Radical cysteine cross-linking proceeds via an orthogonal "click reaction" and yields stable alkyl sulfide products. DAU reacts at physiological pH and cross-linking reactions with peptides, and proteins can be performed at temperatures as low as 4 °C. The central urea bond is efficiently cleaved upon collisional activation during tandem MS experiments generating characteristic product ions. This improves the reliability of automated cross-link identification. Different radical initiators have been screened for the cross-linking reaction of DAU using the thiol-containing compounds cysteine and glutathione. Our concept has also been exemplified for the biologically relevant proteins bMunc13-2 and retinal guanylyl cyclase-activating protein-2. Graphical abstract ᅟ.
Calmodulin (CaM) is a highly conserved Ca-binding protein that is exceptionally abundant in the brain. In the presynaptic compartment of neurons, CaM transduces changes in Ca concentration into the regulation of synaptic transmission dynamics. Areas covered: We review selected literature including published CaM interactor screens and outline established and candidate presynaptic CaM targets. We present a workflow of biochemical and structural proteomic methods that were used to identify and characterize the interactions between CaM and Munc13 proteins. Finally, we outline the potential of ion mobility-mass spectrometry (IM-MS) for conformational screening and of protein-protein cross-linking for the structural characterization of CaM complexes. Expert commentary: Cross-linking/MS and native MS can be applied with considerable throughput to protein mixtures under near-physiological conditions, and thus effectively complement high-resolution structural biology techniques. Experimental distance constraints are applicable best when obtained by combining different cross-linking strategies, i.e. by using cross-linkers with different spacer length and reactivity, and by using the incorporation of unnatural photo-reactive amino acids. Insights from structural proteomics can be used to generate CaM-insensitive mutants of CaM targets for functional studies in vitro or ideally in vivo.
Exploring the interactions between the Ca2+ binding protein calmodulin (CaM) and its target proteins remains a challenging task. Members of the Munc13 protein family play an essential role in short-term synaptic plasticity, modulated via the interaction with CaM at the presynaptic compartment. In this study, we focus on the bMunc13-2 isoform expressed in the brain, as strong changes in synaptic transmission were observed upon its mutagenesis or deletion. The CaM–bMunc13-2 interaction was previously characterized at the molecular level using short bMunc13-2-derived peptides only, revealing a classical 1–5–10 CaM binding motif. Using larger protein constructs, we have now identified for the first time a novel and unique CaM binding site in bMunc13-2 that contains an N-terminal extension of a classical 1–5–10 CaM binding motif. We characterize this motif using a range of biochemical and biophysical methods and highlight its importance for the CaM–bMunc13-2 interaction.
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